The formation and disruption of conducting filament (CF) are responsible for the SET/RESET switching of resistive random access memory (ReRAM). The ReRAM enters into a low resistive state soon after the complete formation of CF and the process is followed by the radial growth of CF during the ON-state. The present investigation aims to develop a numerical and analytical model to realize the effect of CF radius on local temperature rise and activation power, combining the thermal reaction model (TRM) and power signature model. The numerical investigation is carried out using finite element method to obtain the local temperature rise and temperature distribution across the device. The numerical results show a similar increment pattern of local temperature as of analytical TRM i.e. the local temperature increases linearly with a rapid growth rate of ∼63% in initial CF radii and then gradually attains a steady-state temperature with ∼10% increment in higher CF radii. The relationship between resistance and compliance current is calculated which obeys the same reported trend in other switching oxides like TiO X , CuO, NiO. Additionally, the activation power is determined where the resistance decreases (101.87-0.25 KΩ) due to the CF radial growth, which results in four orders of exponential increment in activation power from ∼0.04 µW to 500 ± 100 µW. The power signature of numerical TRM is validated with that analytical TRM where the device attends a steady-state temperature after a certain CF radius (>25 nm) along with the activation power.
The appropriate inflow control valve (ICV) design plays an important role for achieving adequate proactive reservoir management, production management and improving oil recovery. The smart completion consisting of custom designed inflow control valves along with downhole gauges are proven to be the great tool for maximizing sweep efficiency in Minagish Field, West Kuwait. The demonstrated benefits include reduction of unwanted water production, equalization of inflow profile, elimination of cross flow across laterals in multilateral wells and optimization of water injection allocation resulted in increasing sustained well productivity and maximizing oil recovery. Further the downhole gauges provides required reservoir surveillance data on real time for effective reservoir and production monitoring. Moreover the real time surveillance and production control capabilities over entire well life enabled ability to take necessary actions at right time for facilitate defensive as well as proactive reservoir management. In addition the intelligent wells are proven to control the distribution of oil, water and gas in a well between different layers, compartments or reservoirs having high degrees of anisotropy and heterogeneity. The smart completions having optimally designed downhole inflow control valves are implemented in oil producers, water injectors, multilateral wells with ESP (Electrical Submersible Pump) and smart dump flood water injectors in Minagish Field. An integrated novel workflow is developed and multi-disciplinary team approach was followed for planning and design of smart completions by considering reservoir properties, geological data, petro-physical data and related uncertainties. Further the various production scenarios, well management scenarios, reservoir dynamics, reservoir uncertainties and reservoir management objectives were considered to select the most appropriate flow trim design of multi-position inflow control valves for wells having multi-zone intelligent completion, smart multilaterals and smart dump flood completions. Also, the right flow control option is included in well design, as it has an impact on the number of zones/intervals that can be realistically controlled in one well, and may affect the overall reliability of the integrated system. Previous field experiences have shown that the resulting benefits are diminished when the front end engineering does not considered suitable inflow control valve design and choke setting tailored to reservoir requirements and inherent uncertainties. The consequences of poor inflow control valve design is realized and found that only few choke positions are usable resulting in non-optimum well performance. Lessons learned from previous wells were incorporated in the new smart wells design and integrated workflow is developed by including the reservoir properties, reservoir dynamic response (e.g. water encroachment and time to breakthrough) and well operating constraints. The paper covers a novel workflow for inflow control valve design and chokes setting stepping distribution that assimilates reservoir properties, wellbore and production constraints. Also the paper details about established reservoir management and production management achieved by properly designed intelligent completions supported with long term well performance results.
The bipolar switching phenomenon is observed in the MgO-based memory cell having a metal-oxide-metal (W/MgO/Cu) structure. The MgO thin film offers a high transmittance of 86 - 88% for visible light, measured by UV-Visible spectroscopy. An optical bandgap of 4.2 eV is estimated from Tauc’s plot calculation from the absorption spectra of MgO thin film. In addition, the XPS scan on the O 1s and Mg 2p peaks reveals the types of chemical elements in the rf sputtered MgO thin film. The Mg 2p peak at 49.36 eV suggests the oxidization of Mg, and two peaks at 529.5 eV and 531.6 eV in the O 1s core level indicate the presence of lattice and non-lattice oxygen, respectively. Non-lattice oxygen is responsible for the resistive switching in oxide thin films, confirmed by electrical characterization. The I-V characteristic from the electrical measurement shows the SET and RESET transitions at 5 V and –5 V, respectively. Moreover, the experimental results provide information about Ohmic conduction in low and high resistive states. This work proposes MgO as a promising material for applications in next-generation non-volatile data storage applications.
Water coning is a serious problem in horizontal wells in Burgan reservoir of Minagish field located in West Kuwait. The reservoir consists of massive channel sands with active bottom aquifer and having very high permeability in the order of few Darcy. The reservoir contains medium quality crude having viscosity of about 30 cp with mobility ratio of 30 to 40. The localized increase in drawdown at sand-face due to high liquid production rate results in early water breakthrough in most of the horizontal wells, even with high stand off from OWC (Oil Water Contact). After water breakthrough the water cut in the wells starts increasing strictly, resulting in by passed oil region below horizontal well. As producing water-oil ratio starts increasing, the operating cost of the well and oil production cost starts rising significantly. In one of the horizontal well of Burgan reservoir, the water cut increased to 90% over a very short period of production and the water cone could not subside even after the well was shut-in for almost three years, confirmed by running the water saturation logs in the subject well as well as in the nearby offset wells. The water saturation logs clearly indicates the oil water interface and the extent of water coning.The paper covers an analytical model developed for horizontal well to predict the critical drawdown, critical production rate, extent of water coning, time for water breakthrough and shut-in time required to subside the cone for very high mobility Burgan reservoir. The predicted results are in agreement with the actual well performance and production logging results.The detailed coning study and model presented in this paper have assisted in planning the advanced completion techniques like Inflow Control Device (ICD) and intelligent multilateral wells with ICD, ICV (Inflow Control Valve) completions to address the severe water coning problems. This allows uniform depletion of reservoir below the horizontal wells for facilitating the steady water-oil interface upward movement below the wellbore. Also the horizontal wells will be placed at optimum distance from the OWC to maximize oil recovery and minimizing the risk of by passed oil. IntroductionThe Minagish field is located in the West Kuwait (figure 1) is a north-south trending anticline with hydrocarbon contained in six major reservoirs ranging in age from early Jurassic to late Cretaceous. The Minagish field contains both sandstone and carbonate reservoirs. The Burgan sandstone reservoir consists of clastic material with minor amounts of carbonatic cements, which appear in the transition zone between continental to marine dominated environments. Generally the sand bodies, silt and shale layers are sedimented randomly within the formation. The general facies trend within the Burgan formation is from a low stand system into high stand system units. The best developed reservoir parts are having higher porosity and ultra high permeability in the order of few Darcy. The reservoir is underlain by an active aquifer causing the bottom w...
Advanced smart multilateral wells with extended reservoir contact from a single well location have accelerated sustained oil production and increases hydrocarbon recovery from ultra-high water mobility oil-wet Burgan reservoir in Minagish Field West Kuwait. Further the smart multilateral wells have proven to be a great tool for adequate proactive reservoir management and production management without well interventions. The Burgan reservoir has active aquifer, very high permeability sands associated with active faults and contain highly viscous reservoir fluid with downhole viscosity of more than 40cp, enhance water mobility and resulted in premature water breakthrough with increasing water cut trend within few months of production in existing horizontal wells. This has resulted into non-uniform reservoir depletion, by-passed oil regions and low oil recovery. The smart level-4 multilateral wells were successfully designed and implemented in Burgan reservoir by combining the reliable Level-4 junction along with stacked dual lateral completion having customized viscosity independent Inflow Control Device (ICD), customized two Inflow-Control Valves as well as down hole gauges, wide operating range Electrical Submersible Pump (ESP), suitable wellheads, X-MAS tree and Integrated surface panel for real time data monitoring first time in Kuwait. The improved production performance of smart multilateral wells in Burgan reservoir of Minagish Field, West Kuwait have achieved appropriate production management through flow regulations across laterals and adequate reservoir management with the combination of inflow control device as well as inflow control valves along with downhole pressure temperature gauges. Moreover the smart multilateral wells have enhanced sustained oil production, maximizes hydrocarbon recovery at lowered capital and operational expenditure resulted in improved economic performance of reservoir with significant increase in net present value (NPV). The paper covers the successful implementation of smart multilateral wells and its effectiveness in achieving the life-cycle production management as well as proactive reservoir management supported with actual well performance results. Further the paper details about the economic benefits of smart multilateral wells and its contribution in improving the economic performance of Burgan reservoir of Minagish Field, West Kuwait.
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